Rami Ahmad El-Nabulsi | Nanophotonics and Nanoelectronics | NanoPhotonics Pioneer Award

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Prof. Dr. Rami Ahmad El-Nabulsi | Nanophotonics and Nanoelectronics | NanoPhotonics Pioneer Award

Professor | Czech Education and Scientific Network(CESNET) | Czech Republic

Prof. Dr. Rami Ahmad El-Nabulsi is a highly prolific theoretical scientist with a distinguished global research profile reflected by 6,964 citations, 386 scholarly documents, an h-index of 43, and an i10-index of 201. His research contributions span theoretical and mathematical physics, applied mathematics, and interdisciplinary modeling, with a strong emphasis on nonlocal, fractional, and fractal frameworks. He has authored several hundred peer-reviewed journal articles published in high-impact international journals, addressing complex problems in quantum dynamics, nonlinear systems, fractal and fractional calculus, quantum field theory, condensed matter physics, superconductivity, plasma and nuclear physics, fluid dynamics, astrophysics, and space science. His work is widely recognized for introducing innovative mathematical operators, generalized Lagrangian and Hamiltonian formalisms, and fractal-based models that advance understanding of classical and quantum phenomena across multiple length scales. Prof. Dr. Rami Ahmad El-Nabulsi has also made notable contributions to applied domains including energy systems, nanomaterials, biophysics, biomedical heat transfer, geophysics, and ocean and atmospheric dynamics. In addition to extensive journal publications, his scholarly output includes books, conference proceedings, and invited research papers. He is internationally acknowledged for research excellence through prestigious awards and recognitions, serves as an editor and editorial board member for numerous reputed journals, acts as a reviewer for a very large number of international journals, and frequently contributes as a conference chair, keynote speaker, and scientific committee member, underscoring his sustained impact, innovation, and leadership in global research.

Profiles: Scopus | ORCID | Google Scholar | ResearchGate | Sci Profiles | Loop

Featured Publications

1. El-Nabulsi, R. A., & Torres, D. F. M. (2008). Fractional action-like variational problems. Journal of Mathematical Physics, 49(5), 053521.

2. El-Nabulsi, R. A. (2005). A fractional approach to non-conservative Lagrangian dynamical systems. FIZIKA A, 14(4), 289–298.

3. El-Nabulsi, R. A., & Torres, D. F. M. (2007). Necessary optimality conditions for fractional action-like integrals of variational calculus with Riemann–Liouville derivatives of order (α, β). Mathematical Methods in the Applied Sciences, 30(15), 1931–1939.

4. El-Nabulsi, R. A. (2005). A fractional action-like variational approach of some classical, quantum and geometrical dynamics. International Journal of Applied Mathematics, 17, 299–317.

5. El-Nabulsi, R. A. (2013). Non-linear dynamics with non-standard Lagrangians. Qualitative Theory of Dynamical Systems, 12(2), 273–291.

Sunkook Kim | Nanophotonics and Nanoelectronics | Best Researcher Award

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Prof. Dr. Sunkook Kim | Nanophotonics and Nanoelectronics | Best Researcher Award

Professor | Sungkyunkwan University | South Korea

Prof. Dr. Sunkook Kim is an internationally recognized scientist whose pioneering contributions lie at the intersection of 2D materials, nanoelectronics, and flexible device engineering. With over 9,566 citations, 231 publications, and an h-index of 46, his research has profoundly influenced advanced materials and next-generation electronic systems. His work encompasses high-mobility transistors, flexible OLED and micro-LED displays, nanostructured memristors, neuromorphic sensors, and anticounterfeiting technologies based on MoS₂, WS₂, and transition metal dichalcogenides (TMDs). His studies have been featured in Nature Electronics, Nature Communications, Advanced Materials, ACS Nano, and Advanced Functional Materials, many highlighted as cover articles, reflecting the high impact of his research. Prof. Dr. Sunkook Kim’s R&D achievements bridge fundamental material synthesis and device integration, leading innovations in stretchable electronics, haptic feedback systems, and large-area 2D semiconductor devices. He has developed laser-assisted fabrication techniques and MoS₂-based biosensors for healthcare and optoelectronic applications, fostering sustainable and low-power device technologies. A recipient of the Korean President’s Young Scientist Award and the Scientist of the Month Award by the National Research Foundation of Korea, he has earned national recognition for his research excellence. His academic leadership extends to editorial board service, peer reviewing for top-tier journals, and conference chairing in nanotechnology and materials science forums. Prof. Dr. Sunkook Kim’s laboratory at Sungkyunkwan University is a hub of interdisciplinary collaboration, supported by multiple national and industrial funding projects, advancing Korea’s competitiveness in nanomaterials research and flexible electronics. His continuing innovations are redefining frontiers in next-generation semiconductors, photonic devices, and intelligent sensing systems.

Profiles: Scopus | ORCID | Google Scholar | ResearchGate | Sci Profiles | IEEE Xplore

Featured Publications

1. Kim, S., Konar, A., Hwang, W. S., Lee, J. H., Lee, J., Yang, J., Jung, C., Kim, H., … (2012). High-mobility and low-power thin-film transistors based on multilayer MoS₂ crystals. Nature Communications, 3(1), 1011.

2. Choi, W., Cho, M. Y., Konar, A., Lee, J. H., Cha, G. B., Hong, S. C., Kim, S., Kim, J., … (2012). High‐detectivity multilayer MoS₂ phototransistors with spectral response from ultraviolet to infrared. Advanced Materials, 24(43), 5832–5836.

3. Liu, N., Kim, P., Kim, J. H., Ye, J. H., Kim, S., & Lee, C. J. (2014). Large-area atomically thin MoS₂ nanosheets prepared using electrochemical exfoliation. ACS Nano, 8(7), 6902–6910.

4. Kim, S., Kwon, H. J., Lee, S., Shim, H., Chun, Y., Choi, W., Kwack, J., Han, D., … (2011). Low-power flexible organic light-emitting diode display device. Advanced Materials, 23(31), 3511–3516.

5. Lee, J., Dak, P., Lee, Y., Park, H., Choi, W., Alam, M. A., & Kim, S. (2014). Two-dimensional layered MoS₂ biosensors enable highly sensitive detection of biomolecules. Scientific Reports, 4(1), 7352.

 

Shang Zhou | Nanophotonics and Nanoelectronics | Best Researcher Award

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Mr. Shang Zhou | Nanophotonics and Nanoelectronics | Best Researcher Award

Graduate Student | Gannan Medical University | China

Mr. Shang Zhou is an emerging researcher whose academic pursuits converge at the intersection of medicine, nanomaterials, and semiconductor physics. His core research focus lies in investigating contact characteristics, interface modulation, and the physical mechanisms of van der Waals heterostructures, particularly those involving graphene and gallium nitride (GaN). By integrating theoretical modeling and experimental validation, his work aims to enhance the performance of electronic and optoelectronic devices through optimized heterojunction structures. His major research contribution includes the project “Research on the Contact Characteristics of Graphene/GaN Heterojunction,” which explores how GaN crystal orientation and surface conditions influence contact behaviors in graphene-based systems. This study offers insights into the design of next-generation semiconductor and nanodevice architectures. His publication in Applied Surface Science (SCI-indexed, Vol. 713, 2025) further underscores his role in bridging fundamental materials science with practical device engineering. Mr. Shang Zhou’s innovative capacity is reflected in his extensive intellectual property portfolio, comprising 12 patents—including several invention patents on graphene/GaN interface regulation methods, semiconductor cleaning technologies, and adhesive removal techniques. His patents also extend to applied innovations such as anti-drowning self-rescue devices and photoelectric sensor systems, demonstrating his versatility and translational approach to technology development. Additionally, he holds two software copyrights related to digital safety education and dispute mediation platforms, showcasing his interdisciplinary engagement across science and societal applications. His Scopus metrics indicate 4 research documents with 3 citations and an h-index of 1, representing early yet promising contributions in high-impact research domains. Through his continuous work in nanostructured materials, heterojunction device optimization, and applied nanotechnology, Mr. Shang Zhou exemplifies a researcher dedicated to advancing the frontiers of semiconductor interface physics and nanomaterial-based biomedical engineering.

Profiles: Scopus | ORCID | Scilit

Featured Publications

1. Zhou, S., Meng, Y., Li, J., Cheng, Y., Bao, X., Wang, Z., Deng, H., Yang, Y., Chen, P., Chen, Y., Ouyang, F., Wang, Q., & Zhong, H. (2025). The impact of GaN crystal orientation on the contact properties of single-layer graphene/GaN: A theoretical and experimental study. Applied Surface Science, 713, 164305.

2. Meng, Y., Du, X., Zhou, S., Li, J., Feng, R., Zhang, H., Xu, Q., Zhao, W., Liu, Z., & Zhong, H. (2024). Investigation of persistent photoconductivity of gallium nitride semiconductor and differentiation of primary neural stem cells. Molecules, 29(18), 4439.

Chengqiang Wang | Linear Dichroism | Best Researcher Award

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Dr. Chengqiang Wang | Linear Dichroism | Best Researcher Award

Lecturer | Hubei Key Laboratory of Micro-Nanoelectronic Materials and Devices, School of Intelligent Manufacturing, Hubei University | China

Dr. Chengqiang Wang, Lecturer at the School of Intelligent Manufacturing, Hubei University, is an accomplished researcher specializing in intelligent sensing materials and devices. His research primarily focuses on the design, optical characterization, and functional enhancement of perovskite-based nanomaterials for advanced optoelectronic and energy applications. With over 20 SCI-indexed publications, Dr. Chengqiang Wang has contributed to high-impact journals including Applied Physics Letters, Advanced Functional Materials, Angewandte Chemie International Edition, Nano Energy, and eScience—the latter featuring his work as a cover article. His total first-author SCI impact factor exceeds 85, with 214 citations and an h-index of 10 on Scopus. Dr. Chengqiang Wang’s research has yielded significant insights into electron–phonon coupling, exciton dynamics, and linear dichroism in perovskite nanostructures, pioneering developments in ultrafast transient absorption spectroscopy and optoelectronic device optimization. His innovative studies have advanced the understanding of quantum dot–liquid crystal composites and nanocomposite interactions, contributing to next-generation intelligent sensor technologies. He holds two authorized Chinese invention patents and one published application, covering novel nanomaterial fabrication and electrochemical catalyst design. Dr. Chengqiang Wang has led multiple research projects, including the Jiangsu Graduate Innovation Program, the Outstanding Doctoral Training Project, and the Hubei University Start-up Fund, and has participated in national-level grants from the National Natural Science Foundation of China (NSFC) and Fudan University. Beyond his research, Dr. Chengqiang Wang serves as a Youth Editorial Board Member for eScience (IF=42.9) and Sustainable Engineering Novit (SEn), as well as a reviewer for Materials Research and Development and related journals. A member of the Chinese Optical Engineering Society, Chinese Chemical Society, and Chinese Micro-Nano Technology Society, he has received the Outstanding Contribution Award from eScience for his exceptional editorial and scientific contributions.

Profiles: Scopus | ORCID | Google Scholar | Sci Profiles | Scilit

Featured Publications

1. M. Zhao, J. Wang, C. Wang, Y. Sun, P. Liu, X. Du, H. Pan, H. Li, H. Liang, & J. Guo. (2024). Enriched edge sites of ultrathin Ni₃S₂/NiO nanomeshes promote surface reconstruction for robust electrochemical water splitting. Nano Energy, 129, 110020.

2. T. Song, C. Q. Wang, H. Lu, X. J. Mu, B. L. Wang, J. Liu, B. Ma, J. Cao, C. X. Sheng, & H. L. Zhang. (2024). Achieving strong circularly polarized luminescence through cascade cationic insertion in lead-free hybrid metal halides. Angewandte Chemie International Edition. Advance online publication.

3. X. Zhang, L. Gao, M. Zhao, Y. Miao, Z. Wang, C. Wang, P. Liu, B. Xu, & J. Guo. (2020). Low-temperature direct synthesis of perovskite nanocrystals in water and their application in light-emitting diodes. Nanoscale, 12(11), 6522–6528.

4. C. Wang, T. Song, P. Yan, S. Hu, C. Xiang, Z. Wu, H. Li, H. Zhao, L. Han, & C. X. Sheng. (2023). Observation of electron–phonon coupling and linear dichroism in PL spectra of ultra-small CsPbBr₃ nanoparticle solution. eScience, 3(6), 100185.

5. A. Yi, M. Huangrui, & L. Qingquan. (2017). Study on the influence of the nose slenderness ratio of high-speed train on the aerodynamic noise. Chinese Journal of Theoretical and Applied Mechanics, 49(5), 985–996.